Heat transfer system for warehoused goods
A high efficiency airflow management system can be used to reliably and consistently draw air through palletized product stacks with a minimum of energy expenditure. A racking system is provided with a grid of pallet bays separated from an air plenum/chamber by a wall having an airflow opening for each pallet bays. An air seal is formed at the periphery of each opening by resiliently flexible side seals and a top seal to form a highly airtight interface between the pallet assembly and the adjacent airflow opening. When a pressure differential is developed between the chamber and the pallet bay, air is efficiently drawn substantially exclusively through the pallet assemblies with minimal leakage. The flexible sealing arrangement accommodates pallet assemblies with unevenly stacked rows of cases without significant loss of system efficiency.
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This application claims the benefit under Title 35, U.S.C. § 119(e) of U.S. Provisional Patent Application Ser. No. 62/235,030, entitled HEAT TRANSFER SYSTEM FOR WAREHOUSED GOODS and filed on Sep. 30, 2015, the entire disclosure of which is hereby expressly incorporated by reference herein.
BACKGROUND1. Technical Field
The present disclosure relates to a warehouse that is capable of altering and/or holding steady the temperature of a quantity of product housed in cases forming pallet assemblies and storing such product, e.g., bulk foods. More particularly, the present disclosure relates to spacing, stacking and heat transfer structures used in such a warehouse.
2. Description of the Related Art
Freezer warehouses are known in which large pallets of items including meats, fruit, vegetables, prepared foods, and the like are frozen in blast rooms of a warehouse and then are moved to a storage part of the warehouse to be maintained at a frozen temperature until their removal.
U.S. Pat. No. 8,783,047 entitled “Rack-Aisle Freezing System for Palletized Product”, filed on Sep. 8, 2010, the entire disclosure of which is hereby explicitly incorporated by reference herein, relates to an improved system for freezing food products. Shown in
Air handlers 8, e.g., chillers or heaters (
Adjacent pairs of racking structures 14 (
U.S. Pat. No. 8,919,142 entitled “Swing Seal for a Rack-Aisle Freezing and Chilling System”, filed on Mar. 29, 2011, the entire disclosure of which is hereby explicitly incorporated by reference herein, discloses a top periphery seal useable to seal an intake opening as described above and which automatically adjusts to the height of pallet assembly 52 as illustrated in
In the above described installation, utilizing “egg carton” spacers 20, heat transfer from chilled ambient air in warehouse 2 to the products contained in cases 22 is effected through forced convection which is facilitated by the irregular shape of egg carton spacers 20 to allow airflow in all directions through pallet assembly 52. Alternative spacers such as wood slat spacers may also be utilized to separate cases 22 on pallet 4.
For maximum effectiveness of thermal transfer between the conditioned air in warehouse 2 and the product contained in product cases 22, it is desirable to have air within the spacers continuously refreshed and replaced with conditioned air from warehouse 2. One may to achieve this air movement is to use fans 12 (
The present disclosure provides a high efficiency airflow management system which can be used to reliably and consistently draw air through palletized product stacks with a minimum of energy expenditure. A racking system is provided with a grid of pallet bays separated from an air plenum/chamber by a wall having an airflow opening for each pallet bays. An air seal is formed at the periphery of each opening by resiliently flexible side seals and a top seal to form a highly airtight interface between the pallet assembly and the adjacent airflow opening. When a pressure differential is developed between the chamber and the pallet bay, air is efficiently drawn substantially exclusively through the pallet assemblies with minimal leakage. The flexible sealing arrangement accommodates pallet assemblies with unevenly stacked rows of cases without significant loss of system efficiency.
In certain exemplary embodiments, the racking system may further include an air dam within the plenum which operates to compensate for a vacant bay by automatically closing some or the entire air flow opening upon removal of the pallet assembly from the bay. For example, the air dam may take advantage of the increased air flow which results from removing the pallet assembly from its seal configuration against the air flow opening to pivot or swivel an air dam to a shut position to prevent significant draws of air through the vacant bay and into the plenum. This vacant bay compensation system cooperates with the tight air seal in occupied pallet bays to minimize the power required of the fans serving the plenum.
The disclosure, in one form thereof, provides an installation for warehousing palletized product, comprising: a pallet racking assembly comprising: a pallet receiving space sized and configured to receive a pallet assembly including a pallet and a plurality of vertically stacked rows of cases disposed on the pallet and providing an airflow pathway through the vertically stacked rows of cases; an airflow chamber including an air inlet and an air outlet; an air handler positioned to direct air into the airflow chamber from the air inlet and exhaust air from the airflow chamber through the air outlet; a wall disposed between the pallet receiving space and the airflow chamber, the wall having at least one airflow opening having a substantially planar opening periphery defining an opening plane, the airflow opening sized and positioned to be engaged by the pallet assembly when the pallet assembly is pressed against the opening periphery; a first side seal and disposed along a first side edge of the opening periphery, the first side seal defining a resiliently deformable first seal surface extending from the first side edge into the pallet receiving space, such that the first seal surface faces the pallet receiving space and defines a first obtuse angle with the opening plane; a second side seal and disposed along a second side edge of the opening periphery, the second side seal defining a resiliently deformable second seal surface extending from the second side edge into the pallet receiving space, such that the second seal surface faces the pallet receiving space and defines a second obtuse angle with the opening plane.
The disclosure, in another form thereof, provides an installation for warehousing pallets of product, comprising: a plurality of pallet assemblies, each pallet assembly comprising: a pallet; a plurality of vertically stacked rows of cases disposed on the pallet and providing an airflow pathway through the vertically stacked rows of cases containing the product; and at least one spacer disposed between the plurality of vertically stacked rows of cases, the spacer having a longitudinal airflow channel formed therethrough; and a pallet racking assembly comprising: a plurality of pallet bays having the plurality of pallet assemblies removably received therein; an airflow chamber including an air inlet and an air outlet; an air handler positioned to direct air into the airflow chamber from the air inlet and exhaust air from the airflow chamber through the air outlet; a wall disposed between the plurality of pallet bays and the airflow chamber, the wall having an airflow opening in each of the plurality of pallet bays, each airflow opening having a substantially planar opening periphery defining an opening plane, the airflow opening sized and positioned to be engaged by the pallet assembly when the pallet assembly is pressed against the opening periphery;
The disclosure, in a further form thereof, provides a method of sealing an airflow opening with a pallet assembly, the method comprising: advancing the pallet assembly into a pallet bay along a depth direction until the pallet assembly reaches a seat position adjacent the airflow opening; during the step of advancing the pallet assembly, engaging the pallet assembly with a resiliently flexible left side seal and a resiliently flexible right side seal disposed at the left and right edges of the airflow opening respectively; during the step of engaging, deflecting the left side seal and the right side seal toward the airflow opening along the depth direction and away from the airflow opening along a lateral direction, such that the left side seal and right side seal conform to left and right vertical edges of the pallet assembly respectively; and during the step of advancing the pallet assembly, engaging the pallet assembly with a top seal.
The above mentioned and other features and objects of this disclosure, and the manner of attaining them, will become more apparent and the disclosure itself will be better understood by reference to the following description of embodiments of the disclosure taken in conjunction with the accompanying drawings, wherein:
Corresponding reference characters indicate corresponding parts throughout the several views. Although the exemplifications set out herein illustrate embodiments of the disclosure, in several forms, the embodiments disclosed below are not intended to be exhaustive or to be construed as limiting the scope of the disclosure to the precise forms disclosed.
DETAILED DESCRIPTIONThe present disclosure provides a system and method for efficiently directing air flow through pallet assemblies 52 with a minimum of energy expenditure by the fans which drive such air flow. In particular, and as described in further detail below, the present disclosure provides racking assembly 214 (
In addition, an arrangement of air dams 270 (
1. Palletized Product Environment, Assembly and Arrangement.
Pallet assemblies 52 form a part of warehouse installation 2 depicted, e.g., in
As depicted, e.g., in
With pallet assemblies 52 arranged in rows and columns on racks 14, warehouse installation 2 can be utilized to raise, lower and/or maintain the temperature of a quantity of product contained in cases 22 to a desired set point. As illustrated in
Racks 14 define airflow openings 54 fluidly connected to a chamber 6, which, in the exemplary embodiment illustrated, is enclosed by a pair of end walls 15 and top panel 17. Pallet assemblies 52 are disposed and sealed against the air intake openings formed in racks 14, as described in detail below. Referring to
In one exemplary embodiment, pallet 4 defines a standard 40 inch by 48 inch rectangular outer perimeter. With such a pallet, first surface 32 and second surface 34 of spacer 30 illustrated in
As illustrated in, e.g.,
2. Racking Assembly and Pallet/Rack Interface.
Turning now to
As further described below, each bay 202 includes left side seal 260 and right side seal 262 which cooperate to prevent airflow around the sides of pallet assemblies 52 during operation of the installation, e.g., via air pathways 16 as shown in
As also described further below, each airflow opening 54 may have air dam 270 positioned behind opening 54 (
For purposes of the present disclosure, reference directions relative to racking assembly 214 are taken from the perspective of an operator of racking assembly 214 facing bays 202 from within aisle 10 (
As best seen in
If the various cases 22 and spacers 30 of pallet assembly 52 are evenly stacked upon one another, cases 22 and spacers 30 may cooperate with the adjacent portions of wall 230 to form a marginal air seal in this “fully seated” position of pallet assembly 52. This marginal seal may allow an acceptably low amount of air to flow around pallet assembly 52 and into airflow opening 54, i.e., air pathways 16 (
However, as best seen in
In an exemplary embodiment, side seals 260, 262 extend vertically from the base of airflow opening 54, illustrated as the top of pallet stop frame member 238 in
In the illustrated embodiment, left side seal 260 and right side seal 262 are mirror images of one another about a vertical plane bisecting bay 202 (i.e., a vertical plane extending in the depth direction). Accordingly, both side seals 260, 262 have the same structure and spatial arrangement with respect to the surrounding structures of racking assembly 214, and a reference to left side seal 260 can be taken as a corresponding reference to right side seal 262.
Side seal 260 is made from a resiliently deformable material, illustratively from a series of substantially parallel resiliently deformable fibers 264, as shown in
In addition, the fibers 264 of seal 260 are arranged to collectively present a substantially planar seal surface to the incoming corners of pallet assembly 52, with the seal surface facing into the pallet bay 202 as illustrated in
Although side seals 260, 262 are illustrated as resiliently deformable “brush seals” having seal fibers 264 as described above, it is contemplated that other resiliently deformable materials may be used to create the angled seal surfaces for similar engagement with the left and right corners of pallet assembly 52. For example, it is contemplated that a suitable seal surface can be formed from a sheet of flexible fabric, plastic or latex material stretched within a frame having the desired periphery and orientation. In another alternative, a resiliently deformable block of foam may be used, with the foam forming a sealing surface of similar size, shape, and orientation as the sealing surfaces of seals 260, 262. Moreover, any material may be chosen to form the sealing surfaces of seals 260, 262, provided that the materials present a “tangent” surface to the respective corners of pallet assembly 52 which can deflect to fill or substantially fill respective gaps formed by unevenly stacked cases 22, as shown in
As noted above, swing seals 40 are used at the top portion of airflow opening 54 in order to seal the top inner corner of pallet assembly 52 against the forward facing surface of swing seal 40 to prevent air leakage over the top of pallet assembly 52 and through the top portion of airflow opening 54 when pallet assembly 52 is shorter than opening 54, as shown in
Turning now to
In order to further ensure a substantially air tight sealing engagement between seal surface 64 and pallet assembly 52, weight 68 may be disposed on the dished surface 66 opposite seal surface 64, and positioned nominally rearwardly (i.e., toward chamber 6) of pivot point 60 such that weight 68 creates a moment urging swing seal 40 to pivot inwardly toward pallet bay 202 as illustrated in
In an alternative embodiment shown in
Referring still to
In use, the rearwardly-extending portions of pivot arms 72, 74 and crossbar 76 create a torque or moment about pivot point 60, such that weight assembly 70 contacts the substantially vertical swing seal 40 and urges swing seal 40 into pallet bay 40. Similar to weight 68 described above, this biases swing seal 40 into contact with the upper portion of the cases on any pallet assembly 52 received within bay 202, thereby ensuring a firm and effective seal therebetween. When bay 202 is vacant, however, limit stop brackets 78 are positioned to contact a portion of racking 14, such as a lip or surface of vertical frame members 236 (
The amount of biasing force provided by seal assembly 70 may be varied as required or desired for a particular application. As noted above, weights (not shown) may be fixed to apertures 76A to increase the effective weight of crossbar 76, thereby increasing the moment applied about pivot point 60 and increasing the inward bias of swing seal 40 into bay 202. In addition, the material and geometry of weight assembly 70 may be modified as needed, with heavier materials and increasing rearward protrusion of pivot arms 72, 74 and crossbar 76 into plenum 6 both contributing to increased biasing force. For top-row use in racking 14, such rearward protrusion may be limited to avoid spatial conflict with fans 12, which may protrude downwardly into plenum 6. Accordingly, weight increases may be favored over geometry reconfigurations for increasing bias on swing seal 40 for top-row applications.
In a further alternative embodiment, swing seal 40 could be omitted entirely and a resiliently deformable seal of similar structure and arrangement to left and right side seals 260, 262 could be used along the top portion of the periphery of air flow opening 54. Such an arrangement would be appropriate, for example, where pallet assemblies 52 are expected to have a fixed height which about equal to the height of airflow opening 54.
As noted above, the provision of resiliently deformable side seals 260, 262 and a suitable top seal arrangement, such as swing seal 40 or a third deformable seal, creates a substantially air tight interface between pallet assembly 52 and airflow opening 54 even when pallet assembly 52 does not have even, linear corners and sealing surfaces. This airtight arrangement, in cooperation with the structure and design of air chamber 6 which is also air tight at end walls 15 and top panel 17, facilitates airflow driven by fans 212 almost entirely through the perforations in pallet assembly 52 (e.g., through air channels 38 formed in spacers 30, as shown in
In an exemplary embodiment, fans 212 (
In the illustrated embodiment of
The use of relatively lower-power direct-drive axial fans 212 is enabled by the airtight arrangement of racking 214, such that two or even one 2 horsepower direct drive fan 212 may be used for a set of 8 pallet bays 202 as noted above. This represents a 20-60% efficiency improvement over conventional centrifugal fans 12. Stated another way, a reduced pressure differential within chamber 6 may be used in racking 214 while still performing sufficient heat transfer operations on pallet assemblies 52, as compared to predicate designs. In an exemplary embodiment, a pressure differential of 0.25 inches of water may be sufficient to draw a desired amount of air through pallet assemblies 52 using racking 214, as compared to up to in excess of 1 inch of water for high power centrifugal fan arrangement. In one particular exemplary embodiment, 0.375 inches of water has been found to be more than adequate for blast freezing operations where fans 212 create a vacuum pressure differential in chamber 6 as compared to the ambient pressure within warehouse 2, such that air is drawn through pallet assemblies 52 from the ambient vicinity (e.g., aisles 10 of
As an alternative to fans 212 creating vacuum pressure within chamber 6 as described above, it is contemplated that fans 212 may be reversed to create a relatively higher pressure in chamber 6 compared to the ambient environment, such that airflow is reversed through pallet assemblies 52. In this configuration, air is “pushed” through spacers 30 from airflow opening 54 toward the ambient environment of warehouse 2, rather than being “drawn” through pallet assemblies 52 when fans 212 create a vacuum pressure within chamber 6. In the case where fans 212 blow into chamber 6 to elevate the pressure therein, fans 212 form the inlet of the illustrated embodiment, and airflow openings 54 form the outlet. Conversely, where fans 212 blow outwardly to exhaust air from chamber 6, fans 212 are the outlet and airflow openings 54 are the inlets.
3. Vacant-Bay Compensation.
In addition to the above-described seal arrangement around the periphery of airflow opening 54 and the modular partitioning of chamber 6, efficient heat-transfer operation of racking 214 may be accomplished by avoiding performance reductions when pallet assemblies 52 are removed from bays 202 to create one or more vacant bays 202 as illustrated in
Turning now to
Referring specifically to
Turning to
In another embodiment, air dam 270 may be manually or automatically controllable, such as by pneumatic cylinders with two way actuation. Such cylinders may pivot air dam 270 into the engaged configuration (
In addition, it is contemplated that controller 282 may be provided and operably connected to fan 212 in order to control the pressure differential in airflow through chamber 6 depending on changing conditions, e.g., the number of vacant pallet bays 202 within a given configuration of racking 214. For example, controller 282 may monitor pressure within chamber 6 with a transducer, and compare the measured pressure with a desired set point or a range of set points. When the measured pressure falls by a threshold amount, such as outside the acceptable pre-determined range of pressures, fan 212 may be sped up or a second fan 212 may be activated in order to bring the pressure differential back to a desired set point. Thus, when pallet assemblies 52 are removed from bays 202 increasing airflow to chamber 6, fans 212 may increase speed to compensate as long as necessary. For example, fan 212 may speed up to induce actuation of air dam 270 as shown in
In the illustrated embodiment of
Air dams 270 may be provided in a variety of forms and configurations, as required or desired for a particular application. In one example, air dams 270 may be formed from a series of powered louvers or dampers located inside the plenum space or chamber 6. Such louvers/dampers may be individually pivotable and collectively linked to a single actuator, such that the plurality of louvers can be collectively actuated to block or restrict airflow when a respective bay 202 is unoccupied. Such louvers may be provided in sufficient number and size to block or restrict the air flow path for a single bay 202, or can be provided in a larger number and/or size to block or restrict airflow through a number of bays 202 for certain applications.
In another embodiment, air dams 270 may be provided as an integrated “constant air volume” damper located inside the plenum space or chamber 6, and includes one or more air flow-driven dampers which are arranged and balanced to maintain a constant-volume air flow through opening 54 regardless of whether bay 202 is occupied, unoccupied or partially occupied. Additional details of a commercially available constant air volume damper device is contained in Appendix A, entitled “CVQ Constant Air Volume Damper”, forming a part of the present application, the entire disclosure of which is incorporated by reference herein. In an exemplary embodiment, such a constant air volume damper controls the airflow volume for a single bay 202.
As an alternative to the constant air volume damper described above, a similar system may be provided with a damper designed to deliver a variable air volume. In this embodiment, the damper is located inside the plenum space adjacent bay 202, similar to the embodiment described above. However, when bay 202 is unoccupied airflow volume through opening 54 is significantly reduced as compared to the corresponding airflow volume when bay 202 is occupied by pallet assembly 52. In an exemplary embodiment, such a variable volume damper controls the airflow volume for a single bay 202.
In yet another embodiment, a tilting panel of similar construction to air dam 270 (
In yet another embodiment, a door (similar to air dam 270) may be pivoted about a vertical axis with a hinge positioned at either the left or right of opening 54. When the adjacent bay 202 is unoccupied, the door is swung closed either manually or automatically, e.g., with a door actuator controllable by a switch and/or electronic controller. The door may be positioned inside chamber 6, swinging outwardly away from opening 54 into chamber 6, or may be positioned outside chamber 6 and within bay 202, swinging inwardly into bay 202. If the door swings inwardly, actuation must occur when bay 202 is unoccupied.
In still another embodiment, a roll-up style door may be provided within chamber 6 (i.e., on the chamber side of opening 54) or external to chamber 6 (i.e., on the bay side of opening 54). The roll-up style door is rolled down to cover opening 54 when bay 202 is unoccupied, and rolled up to allow airflow through opening 54 when bay 202 is occupied.
For any of the above-described structures for selectively blocking or allowing airflow through opening 54, an auxiliary opening may be provided within chamber 6 and spaced away from opening 54. This auxiliary opening may take the form of a sheet metal box attached to the chamber side of wall 230, such that the sheet metal fluidly isolates the interior of the box from chamber 6 except through the auxiliary opening. The auxiliary opening is positioned to generally align with opening 54, such that air may flow through both opening 54 and the auxiliary opening as it moves between bay 202 and chamber 6. The auxiliary opening may be selectively blocked in order to selectively interrupt such airflow as described above, rather than directly blocking opening 54. The interior space of the box shifts the selectively blocked airflow opening away from bay 202 and into chamber 6, thereby providing a physical space and volume to accommodate various air blocking structure designs.
While this disclosure has been described as having exemplary designs, the present invention can be further modified within the spirit and scope of this disclosure. This application is therefore intended to cover any variations, uses, or adaptations of the disclosure using its general principles. Further, this application is intended to cover such departures from the present disclosure as come within known or customary practice in the art to which this disclosure pertains and which fall within the limits of the appended claims.
Claims
1. An installation for warehousing palletized product, comprising:
- a pallet racking assembly comprising: a pallet receiving space sized and configured to receive a pallet assembly including a pallet and a plurality of vertically stacked rows of cases disposed on the pallet and providing an airflow pathway through the vertically stacked rows of cases; an airflow chamber including an air inlet and an air outlet; an air handler positioned to direct air into the airflow chamber from the air inlet and exhaust air from the airflow chamber through the air outlet; a wall disposed between the pallet receiving space and the airflow chamber, the wall having at least one airflow opening having a substantially planar opening periphery defining an opening plane, the airflow opening sized and positioned to be engaged by the pallet assembly when the pallet assembly is pressed against the opening periphery; a first side seal disposed along a first side edge of the opening periphery and crossing the opening plane into the pallet receiving space, the first side seal defining a resiliently deformable first seal surface extending from the first side edge into the pallet receiving space, such that the first seal surface faces the pallet receiving space and defines a first obtuse angle with the opening plane at the junction between the first seal surface and the opening plane, the first obtuse angle opening toward the pallet receiving space; a second side seal disposed along a second side edge of the opening periphery and crossing the opening plane into the pallet receiving space, the second side seal defining a resiliently deformable second seal surface extending from the second side edge into the pallet receiving space, such that the second seal surface faces the pallet receiving space and defines a second obtuse angle with the opening plane at the junction between the second seal surface and the opening plane, the second obtuse angle opening toward the pallet receiving space;
- wherein the first side seal and the second side seal are configured and positioned to cooperate to create a substantially planar, airtight interface between a pallet assembly and the airflow opening.
2. The installation of claim 1, wherein:
- the first side seal comprises a first plurality of resiliently flexible fibers extending from the first side edge into the pallet receiving space, the first plurality of resiliently flexible fibers collectively defining the first obtuse angle; and
- the second side seal comprising a second plurality of resiliently flexible fibers extending from the second side edge into the pallet receiving space, the second plurality of resiliently flexible fibers collectively defining the second obtuse angle.
3. The installation of claim 1, wherein the first obtuse angle and the second obtuse angle are both between 135 degrees and 150 degrees, whereby the first seal surface and the second seal surface are configured to undergo substantial deformation in both a depth direction and a width direction when the pallet assembly is advanced into the pallet receiving space and into engagement with the first side seal and the second side seal.
4. The installation of claim 1, wherein the first obtuse angle and the second obtuse angle are both between 120 degrees and 150 degrees, whereby the first seal surface and the second seal surface are configured to undergo substantial deformation in both a depth direction and a width direction when the pallet assembly is advanced into the pallet receiving space and into engagement with the first side seal and the second side seal.
5. The installation of claim 1, wherein the air handler is a fan.
6. The installation of claim 5, wherein the fan is a direct-drive fan having a motor and a fan blade, in which a longitudinal axis of the motor is substantially coaxial with a pivot axis of the fan blade.
7. The installation of claim 1, wherein:
- the first side seal extends vertically from a base of the pallet receiving space to an upper edge of the opening periphery; and
- the second side seal extends vertically from the base of the pallet receiving space to the upper edge of the opening periphery.
8. The installation of claim 7, further comprising a swing seal disposed over an upper portion of the airflow opening and hingedly connected to the wall at a pivot point having a substantially horizontal axis, the swing seal having a movable portion at least partially protruding into the pallet receiving space in an at-rest position, such that the movable portion of the swing seal is positioned to be yieldably moved into the airflow chamber when the pallet assembly is pressed against the opening periphery.
9. The installation of claim 8, wherein the swing seal comprises:
- a seal surface facing the pallet receiving space;
- a dished surface facing rearwardly away from the pallet receiving space and the pivot point for the hinged connection being within the dished surface; and
- a weight disposed within the dished surface and positioned rearwardly of the pivot point to create a moment, such that the seal surface is pivoted further inwardly toward the pallet receiving space in the at-rest position as compared to the swing seal lacking the weight.
10. The installation of claim 8, wherein the swing seal comprises:
- a seal surface facing the pallet receiving space;
- a rear surface facing rearwardly away from the pallet receiving space; and
- a weight coupled to the swing seal and pivotable about the pivot point, the weight positioned rearwardly of the swing seal and the pivot point to create a moment, such that the seal surface is pivoted further inwardly toward the pallet receiving space in the at-rest position as compared to the swing seal lacking the weight.
11. The installation of claim 10, wherein the weight comprises:
- a pair of pivot arms pivotably connected at the pivot point, the pivot arms extending downwardly from the pivot point and rearwardly away from the rear surface of the swing seal;
- a cross bar extending between the pair of pivot arms and positioned generally opposite the pivot point;
- at least one stop limit bracket disposed on at least one of the pair of pivot arms, the stop limit bracket positioned to abut the pallet racking assembly when the swing seal is inwardly biased toward the pallet receiving space by a desired amount.
12. The installation of claim 1, in combination with the pallet assembly received in the pallet receiving space and sealingly engaged with the airflow opening via the first side seal and the second side seal.
13. The installation of claim 12, wherein the pallet assembly includes a spacer disposed between respective vertically stacked rows of cases, the spacer providing the airflow pathway by separating respective ones of the plurality of vertically stacked rows of cases from one another.
14. The installation of claim 1, further comprising a warehouse defining a warehouse space set to a desired air temperature and housing the pallet racking assembly, the pallet racking assembly disposed in the warehouse space.
15. The installation of claim 14, further comprising an air conditioner operably connected to the warehouse space to deliver conditioned air to the warehouse space, the conditioned air providing the desired air temperature.
16. The installation of claim 15, wherein the air conditioner comprises one of a chiller and producing freezing air and a heater producing warmed air, whereby freezing or warmed air can flow through the airflow pathway of the pallet assembly to thereby freeze or thaw a product contained in the vertically stacked rows of cases.
17. The installation of claim 1, wherein:
- the pallet racking assembly comprises a plurality of the pallet receiving spaces arranged in vertically spaced horizontal rows;
- the wall includes a plurality of the airflow openings respectively disposed at each of the plurality of the pallet receiving spaces, whereby the pallet racking assembly is configured to accommodate a plurality of pallet assemblies; and
- each of the plurality of the airflow openings includes the first side seal and the second side seal disposed at its respective opening periphery.
18. The installation of claim 1, further comprising:
- an air dam disposed in the airflow chamber proximate the airflow opening, the air dam pivotable between a disengaged configuration in which air is allowed to flow freely around the air dam and through the airflow opening, and an engaged configuration in which air is restricted from flowing through the airflow opening by the air dam.
19. The installation of claim 18, wherein the air dam is perforated to allow a desired amount of air flow therethrough in the engaged configuration, the desired amount of air flow less than the free flow of air in the disengaged configuration.
20. An installation for warehousing pallets of product, comprising:
- a plurality of pallet assemblies, each pallet assembly comprising: a pallet; a plurality of vertically stacked rows of cases disposed on the pallet and providing an airflow pathway through the vertically stacked rows of cases containing the product; and at least one spacer disposed between the plurality of vertically stacked rows of cases, the spacer having a longitudinal airflow channel formed therethrough; and
- a pallet racking assembly comprising: a plurality of pallet bays having the plurality of pallet assemblies removably received therein; an airflow chamber including an air inlet and an air outlet; an air handler positioned to direct air into the airflow chamber from the air inlet and exhaust air from the airflow chamber through the air outlet; a wall disposed between the plurality of pallet bays and the airflow chamber, the wall having an airflow opening in each of the plurality of pallet bays, each airflow opening having a substantially planar opening periphery defining an opening plane, the airflow opening sized and positioned to be engaged by the pallet assembly when the pallet assembly is pressed against the opening periphery; a first side seal disposed along a first side edge of the opening periphery and crossing the opening plane into the pallet receiving space, the first side seal defining a resiliently deformable first seal surface extending from the first side edge into a respective pallet bay, such that the first seal surface faces the pallet bay and defines a first obtuse angle with the opening plane at the junction between the first seal surface and the opening plane, the first obtuse angle opening toward the pallet receiving space; a second side seal and disposed along a second side edge of the opening periphery and crossing the opening plane into the pallet receiving space, the second side seal defining a resiliently deformable second seal surface extending from the second side edge into the respective pallet bay, such that the second seal surface faces the pallet bay and defines a second obtuse angle with the opening plane at the junction between the second seal surface and the opening plane, the second obtuse angle opening toward the pallet receiving space; and
- wherein the first side seal and the second side seal cooperate to create a substantially planar, airtight interface between a respective one of the plurality of pallet assemblies and the adjacent airflow opening.
21. The installation of claim 20, wherein the first obtuse angle and the second obtuse angle are both between 135 degrees and 150 degrees, whereby the first seal surface and the second seal surface are configured to undergo substantial deformation in both a depth direction and a width direction when a respective one of the plurality of pallet assemblies is advanced into a respective one of the plurality of pallet bays and into engagement with the first side seal and the second side seal.
22. The installation of claim 20, wherein the first obtuse angle and the second obtuse angle are both between 120 degrees and 150 degrees, whereby the first seal surface and the second seal surface are configured to undergo substantial deformation in both a depth direction and a width direction when a respective one of the plurality of pallet assemblies is advanced into a respective one of the plurality of pallet bays and into engagement with the first side seal and the second side seal.
23. A method of sealing an airflow opening with a pallet assembly, the method comprising:
- advancing the pallet assembly into a pallet bay along a depth direction until the pallet assembly reaches a seated position adjacent the airflow opening;
- during the step of advancing the pallet assembly, engaging the pallet assembly with a resiliently flexible left side seal and a resiliently flexible right side seal disposed at the left and right edges of the airflow opening respectively; wherein the left side seal is disposed along the left edge of the airflow opening, and the right side seal is disposed along the right edge of the airflow opening, wherein a wall is disposed between the pallet bay and an airflow chamber, the airflow opening being formed in the wall and defining a substantially planar opening plane coincident with the airflow opening; the left side seal defining a resiliently deformable left seal surface extending from the left edge of the airflow opening and crossing the opening plane into the pallet receiving space, such that the left side seal surface faces the pallet receiving space and defines a first obtuse angle with the opening plane at the junction between the left seal surface and the opening plane, the first obtuse angle opening toward the pallet receiving space; the right side seal defining a resiliently deformable right seal surface extending from the right edge of the airflow opening and crossing the opening plane into the pallet receiving space, such that the right seal surface faces the pallet receiving space and defines a second obtuse angle with the opening plane at the junction between the right seal surface and the opening plane, the second obtuse angle opening toward the pallet receiving space;
- during the step of engaging, deflecting the left side seal and the right side seal toward the airflow opening along the depth direction and away from the airflow opening along a lateral direction, such that the left side seal and right side seal conform to left and right vertical edges of the pallet assembly respectively;
- wherein the step of engaging the pallet assembly with the left side seal and the right side seal comprises creating a substantially planar, airtight interface between the pallet assembly and the airflow opening; and
- during the step of advancing the pallet assembly, engaging the pallet assembly with a top seal.
24. The method of claim 23, wherein the step of engaging the pallet assembly with the top seal comprises abutting a top edge of the pallet assembly with a seal surface of a swing seal, such that the swing seal pivots inwardly into the airflow opening.
6340043 | January 22, 2002 | Paupardin |
8459180 | June 11, 2013 | Paupardin |
20100032105 | February 11, 2010 | Drifka |
20130263614 | October 10, 2013 | Tippmann |
Type: Grant
Filed: Sep 30, 2016
Date of Patent: Feb 5, 2019
Patent Publication Number: 20170086485
Assignee: Tippmann Companies LLC (Fort Wayne, IN)
Inventor: Daniel J. Tippmann (Fort Wayne, IN)
Primary Examiner: Emmanuel Duke
Application Number: 15/282,496
International Classification: A23L 3/36 (20060101); F25D 13/00 (20060101); F25D 17/04 (20060101); F25D 17/06 (20060101); F25D 25/02 (20060101);